HU222520B1 - Bone reamer for sharping bone sockets or cavities during orthopaedic surgery - Google Patents

Abstract

FIELD OF THE INVENTION is equipped with. The invention further relates to a kit for use in orthopedic surgery. The bone auger according to the invention is characterized in that the cutting edges (24, 44) have a plurality of longer main cutting edges (24) extending from the lower to the upper part of the cutting head (10) and a larger number of main cutting edges (24) but 24) are made of outer circumferential cutting edges (24) of less than its length, arranged at the bottom of the cutting head (10) at the same angle around the axis of rotation (A). The orthopedic surgical kit is characterized in that it comprises a bone drill according to the invention and a one-cup or cap-shaped prosthetic element, which prosthesis is then arranged at the bottom by a cylindrical inlet wall part of a drilled hip joint. ŕ

Description

Scope of the description is 10 pages (including 4 pages)

EN 222 520 Bl

Field of the Invention The present invention relates to the field of bone-breakers or boreholes for shaping bone incisions or cavities to a desired shape during orthopedic surgery.

In particular, but not exclusively, the invention is applicable to the process of trimming the pelvic cavity, the cavity (acetabulae) of the pelvis to the desired shape for implanting a hip joint or cap. Therefore, prior art techniques are described with reference to cutting or drilling tools for shaping hip joints, and problems with the use of these known tools. A preferred embodiment of the vanes according to the invention is particularly useful for hip joints described in WO 95/17140. However, the bundle of the present invention may also be used to form cavities for receiving other articular prostheses.

Conventional boreholes for bone cavities include a cutting head that rotates around a rotational axis during use and removes material from the cavity, and this cutting head is formed with a full hemispherical wall defining a substantially enclosed inner cavity. There are a number of relatively small, outwardly extending dome-shaped cutting members, each of which defines a small cutter, which is cut-off or otherwise formed in the hemispherical wall. This design is commonly referred to as "cheesecake". Each cutting element forms a narrow passage that leads from the outer hemispherical surface to the inner chamber of the cutting head. In order to avoid undesirable interference during the cutting operation, the cutting elements are normally distributed in an asymmetric shape along the hemispherical outer surface. In a preferred embodiment, the cutting edges may be distributed along a helical line in the direction of the rotational axis.

The disadvantage of this conventional type of chopper is that it has a substantially closed shape and has a number of small dome-shaped cutting elements, so that loosely located cut-out material (debris) will be present at the site of the cutting operation. This is a consequence of the substantially closed cutterhead and the fact that the dome-shaped cutting elements only provide a narrow transition for the cut material. The presence of loose material at the cutting site can lead to inaccurate cavity formation where unwanted gaps are found between the surface of the cavity and the hip joint inserted thereafter. Bone growth cannot bridge larger gaps, so that a portion of the cup surface is too far away from the bone to facilitate accurate contact. As a result, optimum cup fixation is not obtainable, especially in the case of non-bonded prosthetic components, where said slits may reduce initial and longer-term stability. The loose material may cause the bundle to burst, causing undesirable excessive heat generation in the bone tissue, which can damage the vitality of the bone tissue, thereby reducing its ability to create new bone tissue. The formation of new bone tissue is essential for achieving bone integration.

Another known drawback of said known auger is that the cutting operation provided by the relatively small dome-shaped cutting elements will not result in a smooth cavity surface. Instead, each dome-shaped cutting element creates circumferential "macro" sand on the cavity surface during the crushing operation.

It is also disadvantageous for this conventional type of tailgate that the asymmetric distribution of the cutting elements can cause undesirable "swaying" of the trailer during its rotation. Specifically, as a result of the non-symmetrical cutting of the cutting elements on the hemispherical surface, the overall force at each cutting point may result in an uneven load on the cutting head. The load on the cutting head may therefore shift and / or tilt the rotary axis, thereby causing the cavity, the cavity, the cavity to be undesirable, for example an elliptical cross section.

The aforementioned drawback, which occurs in the circumferential grooves, can be reduced by replacing the relatively small dome-shaped cutting elements with longer cutting edges, which are disposed in substantially radial planes along the hemispherical surface as disclosed in U.S. Pat. This document discloses a bone-cutting device for forming cavities, such as a hip joint, comprising a cutting head at one end of a rotary shaft and having a complete hemispherical portion with a substantially closed outer surface. The hemispherical portion defines a substantially enclosed hollow inner chamber and is provided with a plurality of slots connecting the outer surface to the inner chamber. For each slit, the bone material is removed from the cavity by a cutter that protrudes slightly above the hollow surface from the cavity into the inner chamber. In the disclosed embodiment, a cutting edge extends beyond the polar region, i.e. at the point where the rotational axis intersects the hemispherical surface so as to bore the bottom of the cavity.

A flexible quick release device is used to connect and disassemble the cutting head and stem. The cylindrical portion connected to the bottom of the hemispherical portion serves to limit the outward movement of said flexible quick release device.

This prior art document also discloses a well-known borehole technique which initially uses a smaller radius cutting head and then increases the size of the cutting head and thereby increases the radius of the cavity.

A disadvantage of the design disclosed in U.S. Pat. No. 4,131,116 is that an undesirable "catch" or "stall" effect can occur between the cutting device and the edge of the cavity, each time the diameter of the cutting head is increased.

Another disadvantage associated with cutting heads formed as a full-spherical dome is that it is difficult to guide the auger accurately along the selected axis of rotation without the cutting head tilting in the bone cavity.

It is an object of the present invention to provide a bone-breaker that eliminates the known devices hi2

It can be used to make a bone cavity more readily available.

It is an object of the present invention to provide a borehole drill by means of which said "gripping effect" can be eliminated, but at least substantially reduced.

Another object of the present invention is to provide a beaker which eliminates or at least substantially reduces the above-mentioned problem, which results from the cut material present in the cutting site between the beaker and the bone cavity.

It is also an object of the invention to provide a beaker with which a smooth inner surface can be obtained in the bone cavity.

It is a further object of the invention to provide a bundle that can be more easily guided along a predetermined axis of rotation during the cutting operation in order to avoid tipping of the bale relative to said axis.

It is an object of the present invention to provide a kit for orthopedic surgery.

The object of the present invention is achieved by a beaker comprising a cutting head and a cutting head with a lower portion facing the hip joint and a lower portion arranged axially along the axis of rotation of the cutting head and rotating the cutting head around the axis of rotation. characterized by the fact that the cutting edges have a plurality of longer main cutting edges extending from the lower part of the cutting head to the upper portion, and a greater number of major cutting edges, but less than the length of the main cutting edges at the bottom of the cutting head around the axis of rotation they are formed from outer circumferential cutting edges arranged in angular form.

The bone auger according to the invention allows for more precise shaping or beating of the bone cavity compared to the already known bone drill bits. By having more than one cutting edge on the circumference, the load or pressure acting on the circumferential cutting edges decreases as compared to the load on the main cutting edges. The reduced load on the circumferential cutting edges reduces the said "catch", while on the main cutting edges the load can be maintained at a sufficiently high level to ensure proper cutting operation. The problem of the presence of the shredded material in the cutting area is also reduced. This is due to the fact that the number of main cutting edges in the upper part can be reduced to such an extent that the shredded material can be effectively removed from the regions between the main cutting edges. The bone-drill according to the invention is also advantageous for the above-mentioned bone-drill bits having small spherical cutting edges. In the after-drill according to the invention, each of said main cutting edges follows the curvature of the bone cavity, so that no cutting grooves are formed.

In a preferred embodiment, the main cutting edges are formed by suitable stems extending between the upper and lower parts of the cutting head and connecting them. In the regions between adjacent stems, material receiving openings are used to drain the cut material into the internal chamber of the cutting head. The cutting head thus exhibits a substantially cage-like, practically open form. In this context, it should be noted that the trailer could work with a single cutting edge.

In a preferred embodiment, the number of outer circumferential cutting edges of the cutting head is at least twice the number of the main cutting edges. If the number of circumferential cutting edges is a multiple of the number of main cutting edges, it is possible to distribute the circumferential cutting edges evenly over the main cutting edges. Within the scope of the invention, these two numbers and the ratio between them can be very important.

In order to avoid interference in the bleeding operation, the main cutting edges may be "ribbed". It follows that at least a portion of the main cutting edges are divided into smaller cutting edges by grooves or by means of monovalent elements, and that these grooves are arranged in different adjacent cutting edges according to different patterns. The "ribbing" of the main cutting edges is made to ensure the continuous, regular contact of all main cutting edges with the surface of the cavity during the bleed operation. If the edges are not ribbed, there is a risk that the edges "jump" on the surface of the cavity leading to an undesirable interference.

Another way of reducing said interference phenomenon is by placing the main cutting edges and / or circumferential cutting edges around the axis of rotation in an asymmetric pattern, i.e., varying the angular divisions between the individual cutting edges.

It is preferred that the cutting head, with a dome-shaped top portion having a pole region defining the top of the cutting head, the dome-shaped top portion of the cutting head is formed as a hemispherical dome or the dome-shaped top portion as a hemispherical dome cut in the lower section, and all main cutting edges of the cutting head. from the base region of the dome to the pole region of the dome, and at least one of the main cutting edges of the cutting head is formed at the intersection of the cutting head and the dome, while all the main cutting edges of the cutting head are arranged in a radial plane relative to the axis of rotation, and the cutting head is some of the outer peripheral cutting edges. by the end portion of the main cutting edges, while the other outer circumferential cutting edges are separate from the main cutting edges.

In a further preferred embodiment of the bone-drill according to the invention, the main cutting edges of one of the upper parts and the lower part of the cutting head are formed on a connecting rod, and there is a material receiving between the legs, the cut-off material into the inner chamber of the cutting head, and the cutting head is provided. the lower part is provided with an outer peripheral cylindrical surface at least partially received and guided by the hip joint during use in a concentric manner with the axis of rotation, wherein the outer circumferential cylindrical surface of the cutting head is designed to prevent unintentional tilting of the rotational axis.

In a very preferred embodiment of the bone-drill according to the invention, the cutting head has at least two main cutting edges.

BI is where the main cutting edges are arranged symmetrically about the axis of rotation or the main cutting edges are arranged asymmetrically around the axis of rotation.

Such a configuration is advantageous because it is possible to form a cylindrical entry part in the cavity without unacceptably increasing the depth of the cavity formed. The introduction of said cylindrical inlet into the cavity serves the purpose explained below. In a particularly preferred embodiment of this embodiment, the cutting head is provided with a cylindrical bottom portion attached to the truncated dome portion. In forming the bone cavity, the dome-shaped portion of the cutting head penetrates completely into the bone cavity to such an extent that the said cylindrical inlet portion of the bone cavity is formed by the cutting device, thereby penetrating the cylindrical portion of the cutting head at least partially into the cylindrical inlet portion of the cavity. As a result, the cylindrical portion of the cutting head is effectively guided and centered by the bone cavity during the crushing operation to avoid, but at least substantially eliminate, the unintentional tilting of the cutting head.

A further object of the present invention is to provide a bone-hole drill which, in use, with a bottom region facing the bone cavity and along its axis of rotation axially away from the pole region, with a cylindrical edge having an outer cylindrical surface and a rotating axis around the bone cavity is removed from the bone cavity. characterized by a plurality of main cutting edges of defined length extending from the lower part to the upper portion of the cutting head and the outer cylindrical surface of the lower part of the cutting head concentric with the axis of rotation, at least partially in use in the bone cavity and preventing rotation of the rotational axis is designed.

The orthopedic surgical kit according to the present invention consists essentially of a bone-to-fracture and a cap-shaped or cap-shaped prosthetic element, the prosthesis element being arranged at least partially surrounded by a cylindrical inlet wall portion of the cluster.

The above-mentioned and further technical features and advantages of the invention are illustrated in detail with reference to the accompanying drawings, in which:

Fig. 1 is a side elevational view of a bone-piercer according to the invention;

Fig. 2 is a plan view of the beaker according to Fig. 1, a

Fig. 3 is a bottom view of the beaker of Fig. 1, a

Fig. 4 is a perspective view of the bone-piercer shown in Fig. 1;

Figure 5 is a perspective bottom view of the bone-breaker of Figure 1, a

Figure 6 is a cross-sectional view taken along line VI-VI of Figure 2, a

Figure 7 is an enlarged top plan view of a portion of the bone-breaker of Figure 2;

FIG. 1 to 3 is a schematic perspective view of a beaker according to FIGS.

Turning to 1-7. 1 to 4, where identical components are provided with the same reference numerals, are provided with a biting or cutting head 10 according to a preferred embodiment of the invention. This exemplary embodiment is specifically designed to tip the hip joints (acetabulae) in connection with the implantation of hip joints or caps. The use of the auger or cutting head 10 for this purpose will be described later with reference to FIG.

In general terms, the biting or turning cutting head 10 can be divided into three united parts: a frame-like dome-shaped upper part 12, a cylindrical lower part 14 and a quick release portion consisting of two terminals 16, with which the cutting head 10 of the beaker can be releasably connected a manual actuator arm not shown here for rotating the borehole drill around an axis of rotation "A". Both the dome-shaped upper part 12 and the cylindrical lower part 14 have a concentric axis and a circular cross-section with the "A" axis.

The dome-shaped upper part 12 is a truncated hemispherical dome, i.e. a hemispherical dome cut at the bottom. Thus, as shown in Figure 1, the height "h" of the upper part 12 is less than the radius "r". The truncated dome shape comprises an 18-pole region and a base region 20, which are connected by eight shank 22 and are spaced by angles of 45 ° with respect to the axis A. The curvature of the stems 22 determines the curvature of the truncated dome. Each stem 22 has a relatively long cutting edge 24. In this embodiment, the cutting edges are formed by a cutting surface 26 lying in a radial plane parallel to the axis A, and an outlet surface 28, i.e. a backside, which is inclined relative to the cutting surface 26.

The main cutting edges 24 have a plurality of cuts 30, each of which cuts the main cutting edges 24 into smaller cutting edges. In this embodiment, two or three cuts 30 are provided in each stem 22. As a

2, the cuts 30 of the two adjacent arms 22 are in a different radial direction. As a result, the small cutting edges are arranged in a spiral about the axis A, as can be clearly seen in Figure 2. This arrangement of the cutting edges 24 is referred to as ribbed cutting edges, the purpose of which has been mentioned above.

At the 18-pole region of the truncated dome, the shafts 22 are connected by a ring-shaped member 32. Two shafts 22 (one of which passes along line VI-VI of Figure 2) always extend towards and beyond the axis A, thereby ensuring the post-drilling of the hip joint, the bottom of the cavity. The arms 22 and the ring-shaped member 32 define two upper openings 34 in the 18 pole region of the truncated dome.

The cylindrical lower portion 14, which is combined with the upper portion 12, has a cylindrical ring-shaped narrow lower surface 36, a narrow outer cylindrical surface 38, a narrow inner cylindrical surface 40, and a tip provided with a plurality of projections 42 of saw-like shape. From the "A" axis radially, each of the projections 42 has a triangular cross-section. The

Some of the projections 42 have a radial outer surface 43 associated with the outer cylindrical surface 38. The tip of each of the projections 42 has an outer, sloping section formed by a relatively short circumferential 44 cutter.

In the illustrated embodiment, twenty-four outer circumferential edges 44 are disposed at spacings of 15 ° along the circumference of the lower portion 14. Thus, the number of outer circumferential edges 44 is three times the number of main cutting edges 24. One third of the outer circumferential edges 44 is effectively formed by the end section of the main cutting edges 24. Thus, the arms 22 are carried by the cylindrical lower portion 14 and are attached thereto.

The shanks 22, the annular element 32 and the projections 42 define eight relatively large through-openings 46 in the dome-shaped upper portion 12 which extend into an inner chamber formed in the cutting head. As is apparent from the drawings, the cutting head 10 shows a substantially open, basket-like shape.

1-7 Fig. 8 shows the use of the cutting head or borehole 10 shown in FIGS. 8 to 8, with a portion seen from the human pelvis 48 with a hip joint 50 formed with the cutting head 10 and shown in the retracted position in the figure. The outer contour of the cutting head 10, i.e. the truncated dome shape and the cylindrical bottom 14, correspond to the inner contour of the prepared hip joint 50. Thus, the hip joint 50 was clipped to such an extent that the dome-shaped portion, i.e. the cutting edges 24 and 44, formed a cylindrical inner wall portion 52 at the inlet port 50 of the cavity. During the crushing operation, this cylindrical inner wall portion 52 provides a guide surface for the outer cylindrical surface 38 of the cutting head. After the crushing operation, a hip joint, a cap, in particular as described in WO 95/17140, may be inserted into the prepared groove so that the cylindrical bottom portion of the cup is received intimately by the cylindrical inlet of the recessed cavity.

In the above-described embodiment, many modifications are possible. For example, the number of stems 22 and projections 42 can be varied. In fact, it would only be possible to use a single stem 22. Furthermore, the shape of the upper part 12 may differ from the shape of the dome described. Also, the cutting head 10 may be provided with a more compact structure without an internal hollow chamber, but in this case, the debris resulting from the churning must be removed from the main cutting edges by means of channels or equivalent arrangements. In a much simpler embodiment, the cuts 30 may be omitted. The outer circumferential edges 44 may be completely separated from the main cutting edges 24. Finally, the main cutting edges 24 and / or the outer circumferential edges 44 can be positioned with varying angles to avoid interference.

Claims (18)

PATENT CLAIMS 1. A bone drill for forming a hip joint cap comprising a cutting head, the cutting head having an upper portion facing the hip joint and a lower portion spaced axially about the axis of rotation of the cutting head during rotation about the axis of rotation of the cutting head. having cutting edges (24, 44) having a plurality of main cutting edges (24) extending from the lower part of the cutting head (10) to the upper part (12) of the cutting head (10) and more than the number of main cutting edges (24), but formed by outer circumferential cutting edges (24) of less than the length of the main cutting edges (24) arranged at the bottom of the cutting head (10) at an equal angle about the axis of rotation (A). Bone drill according to claim 1, characterized in that the number of outer peripheral cutting edges (44) of the cutting head (10) is at least twice the number of main cutting edges (24). Bone drill according to claim 1 or 2, characterized in that its cutting head (10) is formed by a dome-shaped upper portion (12) having a pole region (18) defining the top of the cutting head (10). Bone drill according to claim 3, characterized in that the dome-shaped upper part (12) of the cutting head (10) is formed as a hemispherical dome. Bone drill according to claim 3, characterized in that the dome-shaped upper part (12) of the cutting head (10) is formed as a hemispherical dome cut at its lower section. 6. Bone drill according to any one of claims 1 to 3, characterized in that each main cutting edge (24) of the cutting head (10) extends from the base region (20) of the dome to the pole region (18) of the dome. 7. A bone drill according to any one of claims 1 to 3, characterized in that at least one of the main cutting edges (24) of the cutting head (10) is formed at the intersection of the axis (A) of the cutting head (10) and the dome. 8. A bone drill according to any one of claims 1 to 3, characterized in that all the main cutting edges (24) of the cutting head (10) are arranged in a radial plane relative to the axis of rotation (A). 9. Bone drill according to any one of claims 1 to 4, characterized in that some of the outer peripheral cutting edges (44) of the cutting head (10) are formed as individual cutting edges separate from the main cutting edges (24) by the end portion of the main cutting edges (24). 10. Bone drill according to any one of claims 1 to 3, characterized in that the main cutting edges (24) are formed between the upper part (12) and the lower part (14) of the cutting head (10) on a connecting link (22) and having a through hole (46) for cutting material into the inner chamber of the cutting head (10). 11. Bone drill according to any one of claims 1 to 3, characterized in that the lower part (14) of the cutting head (10) is formed with an outer circumferential cylindrical surface (38) at least partially accommodated and guided by the hip joint valve (50) . Bone drill according to claim 11, characterized in that the cutting head (10) has an outer circumferential cylindrical f The flange (38) of the Bl 221 520 is designed to prevent unintentional tilting of the axis of rotation (A). 13. A bone drill according to any one of claims 1 to 3, characterized in that the cutting head (10) has at least two main cutting edges (24). Bone remover according to claim 13, characterized in that its main cutting edges (24) are arranged symmetrically about the axis of rotation (A). Bone remover according to claim 13, characterized in that its main cutting edges (24) are arranged asymmetrically about the axis of rotation (A). 16. A13-15. Bone drill according to any one of claims 1 to 3, characterized in that the main cutting edges (24) are ribbed. 17. Bone wrapper for forming a bone cavity as a hip joint, wherein during use, a pivoting material is disposed to pivot about the axis of rotation with the lower portion having an outer cylindrical surface and the axis of rotation about the axis of rotation has a cutting head 5, characterized by a plurality of main cutting edges (24) of defined length extending from the lower part (14) of the cutting head (10) to an upper part (12) and an outer cylindrical surface (14) of the lower part (14) 38) is formed concentric with the axis of rotation (A), at least in part, during use, to fit into the bone cavity and prevent rotation of the axis of rotation (A). 18. A kit for use in orthopedic surgery, wherein the kit of claims 1-16. A bone aspirator according to any one of claims 1 to 5 and a cup or cap shaped member of a prosthetic member which is connected by a tight fit to the cylindrical surface of the prosthetic member and the cylindrical inlet wall portion (52) of the prosthetic hip joint.